scholarly journals Regularly varying measures on metric spaces: Hidden regular variation and hidden jumps

2014 ◽  
Vol 11 (0) ◽  
pp. 270-314 ◽  
Author(s):  
Filip Lindskog ◽  
Sidney I. Resnick ◽  
Joyjit Roy
Keyword(s):  
Regular Variation ◽  
Metric Spaces ◽  
Hidden Regular Variation ◽  
Regularly Varying

scholarly journals Hidden regular variation of moving average processes with heavy-tailed innovations

2014 ◽  
Vol 51 (A) ◽  
pp. 267-279 ◽  
Author(s):  
Sidney I. Resnick ◽  
Joyjit Roy
Keyword(s):  
Sequence Space ◽  
Regular Variation ◽  
Moving Average ◽  
Random Variables ◽  
Continuity Properties ◽  
Hidden Regular Variation ◽  
Constant Coefficients ◽  
Moving Average Processes ◽  
Regularly Varying ◽  
Heavy Tailed

We look at joint regular variation properties of MA(∞) processes of the form X = (Xk, k ∈ Z), where Xk = ∑j=0∞ψjZk-j and the sequence of random variables (Zi, i ∈ Z) are independent and identically distributed with regularly varying tails. We use the setup of MO-convergence and obtain hidden regular variation properties for X under summability conditions on the constant coefficients (ψj: j ≥ 0). Our approach emphasizes continuity properties of mappings and produces regular variation in sequence space.

scholarly journals Hidden regular variation of moving average processes with heavy-tailed innovations

2014 ◽  
Vol 51 (A) ◽  
pp. 267-279
Author(s):  
Sidney I. Resnick ◽  
Joyjit Roy
Keyword(s):  
Sequence Space ◽  
Regular Variation ◽  
Moving Average ◽  
Random Variables ◽  
Continuity Properties ◽  
Hidden Regular Variation ◽  
Constant Coefficients ◽  
Moving Average Processes ◽  
Regularly Varying ◽  
Heavy Tailed

We look at joint regular variation properties of MA(∞) processes of the form X = (X k , k ∈ Z), where X k = ∑ j=0 ∞ψ j Z k-j and the sequence of random variables (Z i , i ∈ Z) are independent and identically distributed with regularly varying tails. We use the setup of M O -convergence and obtain hidden regular variation properties for X under summability conditions on the constant coefficients (ψ j : j ≥ 0). Our approach emphasizes continuity properties of mappings and produces regular variation in sequence space.

scholarly journals Characterizations and Examples of Hidden Regular Variation

Extremes ◽  
2004 ◽  
Vol 7 (1) ◽  
pp. 31-67 ◽  
Author(s):  
Krishanu Maulik ◽  
Sidney Resnick
Keyword(s):  
Regular Variation ◽  
Hidden Regular Variation

scholarly journals A formula for hidden regular variation behavior for symmetric stable distributions

Extremes ◽  
2020 ◽  
Vol 23 (4) ◽  
pp. 667-691
Author(s):  
Malin Palö Forsström ◽  
Jeffrey E. Steif
Keyword(s):  
Power Law ◽  
Spectral Measure ◽  
Regular Variation ◽  
Stable Distributions ◽  
Decay Rates ◽  
Random Vectors ◽  
Power Law Decay ◽  
Exact Power ◽  
Hidden Regular Variation ◽  
Stable Random Vectors

Abstract We develop a formula for the power-law decay of various sets for symmetric stable random vectors in terms of how many vectors from the support of the corresponding spectral measure are needed to enter the set. One sees different decay rates in “different directions”, illustrating the phenomenon of hidden regular variation. We give several examples and obtain quite varied behavior, including sets which do not have exact power-law decay.

scholarly journals One- versus multi-component regular variation and extremes of Markov trees

2020 ◽  
Vol 52 (3) ◽  
pp. 855-878
Author(s):  
Johan Segers
Keyword(s):  
Time Series ◽  
Random Vector ◽  
Regular Variation ◽  
Conditional Independence ◽  
Conditional Distribution ◽  
The Self ◽  
Stationary Time Series ◽  
Markov Tree ◽  
Regularly Varying ◽  
Coupled Random Walks

AbstractA Markov tree is a random vector indexed by the nodes of a tree whose distribution is determined by the distributions of pairs of neighbouring variables and a list of conditional independence relations. Upon an assumption on the tails of the Markov kernels associated to these pairs, the conditional distribution of the self-normalized random vector when the variable at the root of the tree tends to infinity converges weakly to a random vector of coupled random walks called a tail tree. If, in addition, the conditioning variable has a regularly varying tail, the Markov tree satisfies a form of one-component regular variation. Changing the location of the root, that is, changing the conditioning variable, yields a different tail tree. When the tails of the marginal distributions of the conditioning variables are balanced, these tail trees are connected by a formula that generalizes the time change formula for regularly varying stationary time series. The formula is most easily understood when the various one-component regular variation statements are tied up into a single multi-component statement. The theory of multi-component regular variation is worked out for general random vectors, not necessarily Markov trees, with an eye towards other models, graphical or otherwise.

scholarly journals Living on the Multidimensional Edge: Seeking Hidden Risks Using Regular Variation

2013 ◽  
Vol 45 (01) ◽  
pp. 139-163 ◽  
Author(s):  
Bikramjit Das ◽  
Abhimanyu Mitra ◽  
Sidney Resnick
Keyword(s):  
Classical Theory ◽  
Regular Variation ◽  
Environmental Science ◽  
Asymptotic Model ◽  
Multivariate Regular Variation ◽  
Tail Risk ◽  
Risk Estimates ◽  
Hidden Regular Variation ◽  
Definition Of

Multivariate regular variation plays a role in assessing tail risk in diverse applications such as finance, telecommunications, insurance, and environmental science. The classical theory, being based on an asymptotic model, sometimes leads to inaccurate and useless estimates of probabilities of joint tail regions. This problem can be partly ameliorated by using hidden regular variation (see Resnick (2002) and Mitra and Resnick (2011)). We offer a more flexible definition of hidden regular variation that provides improved risk estimates for a larger class of tail risk regions.

scholarly journals On a conjecture of Seneta on regular variation of truncated moments

2021 ◽  
Vol 109 (123) ◽  
pp. 77-82
Author(s):  
Péter Kevei
Keyword(s):  
Distribution Function ◽  
Relative Stability ◽  
Regular Variation ◽  
Domain Of Attraction ◽  
Random Variable ◽  
Nonnegative Random Variable ◽  
Equivalent Characterization ◽  
Regularly Varying ◽  
Normal Law

We prove that h?(x) = ??x0 y??1F?(y)dy is regularly varying with index ? [0, ?) if and only if V?(x) = ?[0,x] y?dF(y) is regularly varying with the same index, where ? > 0, F(x) is a distribution function of a nonnegative random variable, and F?(x) = 1?F(x). This contains at ? = 0, ?= 1 a result of Rogozin [8] on relative stability, and at ? = 0, ? = 2 a new, equivalent characterization of the domain of attraction of the normal law. For ? = 0 and ? > 0 our result implies a recent conjecture by Seneta [9].

scholarly journals Models with hidden regular variation: Generation and detection

2015 ◽  
Vol 5 (2) ◽  
pp. 195-238 ◽  
Author(s):  
Bikramjit Das ◽  
Sidney I. Resnick
Keyword(s):  
Regular Variation ◽  
Hidden Regular Variation

scholarly journals Models with Hidden Regular Variation: Generation and Detection

2015 ◽  
Vol 5 (2) ◽  
pp. 195-238 ◽  
Author(s):  
Bikramjit Das ◽  
Sidney I. Resnick
Keyword(s):  
Regular Variation ◽  
Hidden Regular Variation

Hidden Regular Variation and Detection of Hidden Risks

2011 ◽  
Vol 27 (4) ◽  
pp. 591-614 ◽  
Author(s):  
Abhimanyu Mitra ◽  
Sidney I. Resnick
Keyword(s):  
Regular Variation ◽  
Hidden Regular Variation
Sign in / Sign up

Export Citation Format

Share Document